A torque resisting device for a helicopter, wherein the helicopter includes a body and a main rotor. The device includes a deflector secured to and movable relative to the body, wherein the body includes opposing lateral sides and the deflector is movable to a position to extend away from only one of the lateral sides of the opposing lateral sides. The deflector includes a dimension extending in a plane generally non-parallel to a plane of the main rotor. Further included is a method for counteracting a torque created by the rotation of a main rotor of a helicopter.

Patent
   8430353
Priority
Aug 07 2008
Filed
May 03 2012
Issued
Apr 30 2013
Expiry
Aug 07 2028

TERM.DISCL.
Assg.orig
Entity
Small
2
23
all paid
1. A torque resisting device for a helicopter comprising:
a body comprising opposing lateral sides, wherein only one of the opposing lateral sides comprises a deflector secured to and movable relative to the body such that the deflector is movable to a position to extend away from the one lateral side in a direction nonparallel to a longitudinal axis of the helicopter.
14. A method for counteracting a torque created by the rotation of a main rotor of a helicopter, comprising the steps of:
providing a body of the helicopter comprising opposing lateral sides wherein only one of the opposing lateral sides comprises a deflector secured to and movable relative to the body such that the deflector is movable to a position to extend away from the one lateral side in a direction nonparallel to a longitudinal axis of the helicopter; and
moving the deflector to extend away from the one lateral side of the body.
22. A method for installing a device to counteract a torque created by the rotation of a main rotor of a helicopter wherein the helicopter comprises a body with opposing lateral sides, comprising the steps of:
securing a deflector to the body such that the deflector is movable relative to the body to extend away from only one of the opposing lateral sides in a direction nonparallel to a longitudinal axis of the body, wherein the other of the opposing lateral sides is absent of another deflector secured to the body which would be movable relative to the body to extend away from the other of the opposing lateral sides in a direction non parallel to the longitudinal axis and such that deployment of the deflector would create an imbalanced drag on the helicopter with the helicopter in motion.
2. The torque resisting device of claim 1 wherein the deflector extends away from the body from a position between a main rotor and a tail rotor associated with the body.
3. The torque resisting device of claim 1 further including the deflector rotatably hinged to the body.
4. The torque resisting device of claim 1 wherein the deflector is movable to a deployed position with the deflector extended in a direction forming a desired angle relative to the longitudinal axis of the body with at least a portion of the deflector positioned spaced apart from the body.
5. The torque resisting device of claim 4 wherein the deflector has a non-deployed position with the deflector positioned without extending away from the body.
6. The torque resisting device of claim 5 wherein the deflector is positioned generally along an exterior portion of the body with the deflector in the non-deployed position.
7. The torque resisting device of claim 5 wherein the deflector comprises a portion of the body with the deflector in the non-deployed position.
8. The torque resisting device of claim 7 wherein the deflector is positioned generally flush with the body with the deflector in a non-deployed position.
9. The torque resisting device of claim 4 further comprising a rotation sensing device which senses a number of rotations over a period of time of a tail rotor which is associated with the body, wherein the sensing device is operatively associated with an actuator connected to the deflector such that the deflector is automatically moved to the deployed position with the sensing device sensing at least one of a specified decrease in number of rotations of the tail rotor over a period of time and senses no rotation of the tail rotor.
10. The torque resisting device of claim 9 wherein the sensing device comprises a tachometer.
11. The torque resisting device of claim 4 further comprising a deployment control device which is operatively associated with the deflector to automatically position the deflector to the deployed position at the desired angular relationship relative to the length of the body wherein the deployment control device is operatively associated with at least one of an air speed control device, directional gyro heading indicator, autopilot and Nav Aid.
12. The torque resisting device of claim 11 wherein the deployment control device comprises one of an electrically powered actuator and a hydraulic powered actuator.
13. The torque resisting device of claim 11 wherein the deployment control device comprises right and left pedals, the right and left pedal being operatively associated with the deflector such that an operator of the helicopter may position the deflector at a desired angular position relative to the length of the body by moving the right and left pedals.
15. The method for counteracting a torque of claim 14 the step of providing further includes the deflector extending away from the body from a position between the main rotor and a tail rotor associated with the body.
16. The method for counteracting a torque of claim 14 the step of moving further includes positioning the deflector in a deployed position with the deflector forming a desired angle relative to the longitudinal axis of the body with at least a portion of the deflector positioned spaced apart from the body.
17. The method for counteracting a torque of claim 14 further including the step of sensing rotations of a tail rotor associated with the body wherein with the tail rotor under performing a predetermined number of rotations, the deflector is moved to extend away from the body.
18. The method for counteracting a torque of claim 14 the step of moving includes moving the deflector from a non-deployed position with the deflector not extending away from the body.
19. The method for counteracting a torque of claim 18 the step of moving includes the non-deployed position with the deflector generally aligned with the body.
20. The method for counteracting a torque of claim 14 further providing a deployment control device which is operatively associated with the deflector to automatically move the deflector to a deployed position at a desired angular relationship relative to the length of the body wherein the deployment control device is operatively associated with at least one of an air speed control device, directional gyro heading indicator, autopilot and Nav Aid.
21. The method for counteracting a torque of claim 20 wherein the step of providing a deployment control device comprises providing at least one of a hydraulic and electric actuator being operatively associated with the deflector.
23. The method for installing a device to counteract a torque created by the rotation of a main rotor of a helicopter of claim 22 wherein the step of securing includes positioning the deflector between the main rotor and a tail rotor of the helicopter.
24. The method for installing a device to counteract a torque created by the rotation of a main rotor of a helicopter of claim 22 further including the step of securing one of an electrically powered actuator and hydraulically powered actuator to the deflector.

This application is a continuation of U.S. patent application Ser. No. 12/187,494 filed Aug. 7, 2008.

The present invention relates to helicopters and more particularly to helicopters utilizing a main rotor, and a tail rotor for countering the torque created by the main rotor thereby controlling the lateral movement of the helicopter.

Most helicopters have a single, main rotor but these helicopters also require a separate rotor to overcome torque generated by the main rotor. The single, main rotor blades are generally oriented to rotate in a horizontal plane and the separate rotor blades, often positioned in the tail of the craft, are generally oriented to rotate in a vertical plane.

The single main rotor of a helicopter, as the engine rotates it, creates a counter-torque. The torque causes the body of the helicopter to turn or rotate in the opposite direction that the rotor rotates. The tail rotor, provided with variable pitched blades, through its rotation, either pushes or pulls against the tail to counter the torque imparted by the main rotor to the body of the helicopter.

If the tail rotor fails in flight, engine torque can no longer be countered by the tail rotor, and uncontrolled spinning of the aircraft, driven by the torque generated by the main rotor rotation, is a common result. The pilot has to identify and diagnose the type of tail rotor failure and react accordingly with the correct control strategy within a few seconds to prevent the helicopter from reaching an uncontrollable flight state. There is a need for a device that can automatically provide sufficient torque counter-action upon the loss or failure of a tail rotor to increase the amount of time a pilot has to react to the tail rotor failure thereby increasing the pilot's chances of ultimately safely landing the helicopter. There is also need for a device that can provide sufficient torque counter-action upon the loss or failure of a tail rotor to provide enough directional stability at normal cruising speeds so that a pilot can continue on course or maintain altitude until a suitable landing area is reached.

A torque resisting device for a helicopter wherein the helicopter has a body, a main rotor and a tail rotor comprising a deflector secured to and movable relative to the body, wherein the deflector is positioned between the main rotor and the tail rotor and wherein the deflector is positioned generally aligned with the body in a non-deployed position and a portion of the deflector is positioned spaced apart from the body in a deployed position.

A method for counteracting torque in the operation of a helicopter having a main rotor and a tail rotor following the failure of the tail rotor comprising the steps of providing a deflector secured to the helicopter in a position between the main rotor and the tail rotor, wherein the deflector is positioned generally aligned with a body of the helicopter and deployable to another position wherein a portion of the deflector is positioned spaced apart from the body, deploying the deflector to the other position with occurrence of rotational movement of the body of the helicopter resulting from torque imparted to the body from the rotation of the main rotor.

FIG. 1 is a side elevational view of an example of a helicopter;

FIG. 2 is a partially cut away top view of the helicopter of FIG. 1;

FIG. 3 is a partial cutaway perspective view of the helicopter of FIG. 1 along with an embodiment of a drag resistant deployment device; and

FIG. 4 is a partially cut away top view of the helicopter of FIG. 1 providing a schematic view of pedals and their linkage to the actuator.

FIG. 1 illustrates an example of a helicopter, generally designated 10. In this example, helicopter 10 includes a fuselage 15 having a front portion 20 with a cockpit 25, an intermediate portion 30 and a tail portion 35. A rotary shaft 40 extends upward from the intermediate portion 30 and main rotor 45 is generally horizontally mounted on the rotary shaft 40. The end of the tail portion 35 includes a tail fin 50 which extends generally in a vertical direction from tail portion 35. In this example, the tail rotor 55 is mounted on the tail fin 50 and rotates in a plane generally perpendicular to main rotor 45. It is understood, however, that tail rotor 55 may also be mounted directly in the tail portion 35. Both the main rotor 45 and the tail rotor 55 are driven by an engine of the helicopter 10 through a common transmission and rotate at a certain ratio to each other. For example, the tail rotor 55 may rotate five times for every one time the main rotor 45 rotates. As the engine of the helicopter 10 rotates the main rotor 45 in one direction, torque is created causing the fuselage 15 to rotate in the opposite direction. The rotation of the tail rotor 55 creates a thrust that counteracts the torque that the main rotor 45 produces thereby allowing the helicopter 10 to maintain its heading and provide yaw control.

Yaw is controlled by changing the pitch of the tail rotor 55, thereby controlling thrust. The pitch of tail rotor 55 is controlled by right and left rudder pedals schematic representation of these pedals can be seen in FIG. 4. To turn the nose of the helicopter right, for example, depressing the right rudder pedal decreases the pitch of the tail rotor 55 thereby reducing thrust and the torque then turns the helicopter nose right. Depressing the left rudder pedal increases the pitch of the tail rotor 55 thereby increasing thrust and turning the nose of the helicopter left. A balanced performance between main rotor 45 and tail rotor 55 at normal flight would generally be a neutral position of the right and left rudder pedals. The RPM's of the main rotor 45 and the tail rotor 55 are fairly constant. For instance, if the main rotor 45 is operating at 300 RPM, then the tail rotor is operating at approximately 1500 RPM. There may be a slight variation in the ratio at which the two rotors operate, up to five percent. Undesirable performance of tail rotor 55 would be any drop in RPM's in relationship to the RPM's of the main rotor 45 outside of that five percent variation.

A tachometer 60 is a typical device that senses the number of rotations of, for example, a rotor over a period of time, also mounted on the tail fin 50 and is operatively associated with the tail rotor 55 to sense the (revolutions per minute) RPM's of the tail rotor 55. Tachometers are well known and commonly used in the aircraft industry, and one of ordinary skill in the art would be able to select an appropriate tachometer for use in the present example. While the helicopter 10 in this example utilizes a tachometer 60 to sense the RPM's of the tail rotor 55, any sensing devices known in the art capable of sensing the RPM's of the tail rotor 55 may be used and such data readily compared to the RPM's of the main rotor (also, being monitored by a tachometer, for example) and thereby monitor the two rotors as to whether they are operating within acceptable comparable RPM's for normal operation.

A deployable deflector 65, in this example, is pivotally connected to a side of the tail portion 35 of the fuselage 15. Deflector 65 may be a portion of fuselage 15 or may be a structure separate from fuselage 15. The deflector 65 may be made from standard aircraft materials such as aluminum or composite material such as carbon fiber or the like and is properly reinforced. A deflector lock 67 on the tail portion 35 of the fuselage 15 adjacent the deflector 65 engages the deflector 65 and locks it in a closed position in which the deflector 65 is positioned closely adjacent to or is positioned flush with the side of the tail portion 35 of the fuselage 15.

The deflector 65 is operatively associated with an actuator 70 for deploying of deflector 65 such that at least of portion of the deflector 65 is positioned spaced apart from the body of the helicopter to engage the airflow and provide torque resistance. In the example shown, deflector 65 is hinged to the body of the helicopter such that deflector 65 rotates outwardly in a direction away from the body of the helicopter into a deployed position to provide torque resistance. The actuator 70, for example, can be hydraulic or electric and of the type commonly used in the aircraft industry. The actuator 70 and the deflector lock 67 are operatively associated with the tachometer 60 such that when the tachometer 60 senses a loss of RPM's in the tail rotor 55 below its acceptable RPM's for normal operation, the deflector lock 67 is released and the actuator 70 is automatically activated thereby deploying the deflector 65 to a position transverse to a longitudinal axis of the tail portion 35 of the fuselage 15, shown in FIGS. 2 and 3. The actuator 70 may also deploy the deflector 65 when a signal from the tachometer 60 is lost altogether, for example if the tail rotor 55 is shot off of the helicopter 10.

As the helicopter 10 travels forward at a normal cruising speed, sufficient drag is created by the deflector 65 to counteract the torque created by the rotation of the main rotor 45, enough to allow an operator to maintain its heading and provide yaw control. For instance, if the helicopter 10 is traveling at 120 MPH, a deflector 65 having a surface area of one square foot deployed to a 90 degree angle relative to the fuselage 15 will create a drag force of approximately 1586 lbs/sf to counteract the torque created by the rotation of the main rotor 45. Drag may also be created when the helicopter 10 is hovering and loses thrust created by the tail rotor 55 due to, among other things, failure of the tail rotor 55 or loss of the tail rotor 55 entirely. In such instances, the helicopter 10 will be caused to spin in a direction opposite the rotation of the main rotor 45 as there is no longer a counteracting thrust generated by the tail rotor 55. The rotation of the helicopter 10 will create airflow over the deflector 65 thereby creating drag, which will counteract at least some of the torque created by the rotation of the main rotor 45.

The initial position of the deflector 65 on deployment can be predetermined by a manufacturer or may automatically be controlled by an airspeed indicator, increasing or decreasing the angle of the deflector 65 based on the airspeed of the helicopter 10. The initial deployment of the deflector 65 will immediately start to correct helicopter yaw. After emergency yaw recovery, the position of the deflector 65 may be fine tuned to control yaw. For instance, in the present example, the actuator 70 is also operatively associated with the collective control or cyclic control (not shown) of the helicopter 10. This allows the pilot to trim and fine tune yaw control by adjusting the angle of the deflector 65 with respect to the tail portion 35 of the fuselage 15 following the automatic correction of yaw upon the failure of the tail rotor 55. Manual control can also be initiated by rudder pedals interlinked to the actuator 70, as seen in the embodiment shown in FIG. 4. In FIG. 4, left and right pedals 1 and 2, respectively, are typically used by the pilot to control the pitch of tail rotor 55 in normal flight; however, pedals 1 and 2 can be switched over and be used to control actuator 70, upon tail rotor 55 failure. Pedals 1 and 2, in this embodiment, are linked to actuator 70 such that operation of pedals 1 and 2 by the pilot controls deployment of deflector 65. The linkage and control of the operation actuator 70 are commonly known for operation of controls on an aircraft, such as for example, hydraulic or electrical or combination thereof. Thus with tail rotor 55 not able to counter torque production of main rotor 45, fuselage 15 begins to rotate in a clockwise direction. The pilot can depress left pedal 1 thereby activating actuator 70 to push deflector 65 outwardly away from the fuselage 15 to create drag and provide a counter force to the clockwise rotation of the fuselage 15. Use of left and right pedals 1 and 2 can be employed by the pilot to appropriately trim the deployment of deflector 65 to create sufficient drag to, in turn, trim fuselage 15 into a desired stable orientation. While the actuator 70 in this example is activated by the tachometer 60, it is understood that the actuator 70 may also be operatively associated with a directional gyro heading indicator, an autopilot or any other Nav Aid such that a failure in the tail rotor 55 is acknowledged and the deflector 65 is deployed.

The foregoing description of the various embodiments of the invention have been presented for purposes of illustration and description, and is not intended to be exhaustive or to limit the invention to the precise form disclosed. The description was selected to best explain the principles of the invention and its practical application to enable others skilled in the art to best utilize the invention in various embodiments and various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention not be limited by the specification, but be defined by the claims set forth below.

Botich, Leon

Patent Priority Assignee Title
10124889, May 06 2015 Sikorsky Aircraft Corporation Tail rotor failure recovery controller
8882024, Jun 24 2013 Bell Helicopter Textron Inc. Rotorcraft anti-torque rotor and rudder system
Patent Priority Assignee Title
3081966,
3096953,
3105659,
3188884,
4462559, Sep 07 1982 Means for controlling lateral movement of a helicopter
4708305, Jan 30 1987 The United States of America as represented by the Administrator of the Helicopter anti-torque system using fuselage strakes
4928907, Feb 29 1988 WILLIAM ZUCK; CAROL NIELSON; EILEEN JEFFRESS; DIANE LAMB Compound helicopter with no tail rotor
5188511, Aug 27 1991 United Technologies Corporation; UNITED TECHNOLOGIES CORPORATION A CORP OF DELAWARE Helicopter anti-torque device direct pitch control
5209430, Nov 07 1991 UNITED STATES OF AMERICA, THE, AS REPRESENTED BY THE ADMINISTRATOR OF THE NATIONAL AERONAUTICS AND SPACE ADMINISTRATION Helicopter low-speed yaw control
5388785, Apr 14 1992 Societe Anonyme Dite: Eurocopter France Single-rotor helicopter having a compound anti-torque system, and a method of countering the torque induced by said single rotor
5437419, Nov 06 1992 The United States of America as represented by the United States Rotorcraft blade-vortex interaction controller
5454530, May 28 1993 MCDONNELL DOUGLAS HELICOPTER CO Canard rotor/wing
6036141, Nov 06 1997 McDonnell Douglas Corporation Jet thruster for helicopter antitorque and yaw control system
6352220, Jun 02 2000 The United States of America as represented by the Administrator of the National Aeronautics and Space Administration Helicopter tail boom with venting for alleviation and control of tail boom aerodynamic loads and method thereof
6416015, May 01 2001 Anti-torque and yaw-control system for a rotary-wing aircraft
6755374, Jan 27 2003 Anti-Torque and yaw-control system for a rotary-wing aircraft
6885917, Nov 07 2002 The Boeing Company Enhanced flight control systems and methods for a jet powered tri-mode aircraft
20090277991,
EP1787907,
GB2249770,
JP6286696,
RE42446, Nov 05 2004 EATTS, LLC A VIRGINIA LIMITED LIABILITY CO Emergency anti-torque thruster system
WO2006036147,
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May 03 2012Helicopter Innovations, Inc.(assignment on the face of the patent)
Mar 08 2013BOTICH, LEON A HELICOPTER INNOVATIONS, INC ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS 0299600129 pdf
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